Hsi-Yuan Yang

Intermediate Filaments: Possible Functions as Cytoskeletal Connecting Links Between the Nucleus and the Cell Surface

Intermediate filaments (IF), along with microtubules and microfilaments constitute the three major fibrous protein systems that have been defined by electron microscopical, biochemical, and immunological studies of a wide variety of cell types.’-’ In addition to the major proteinaceous subunits making up the backbone or core of these cytoplasmic fibers (e.g. tubulin in microtubules), there are also numerous “associated proteins” which appear to complex with their walls. These associated proteins are thought to be involved in various functions, including crosslinking and the regulation of polymerization. Numerous examples of such associated proteins can be found in the literature including many of the actin or microfilament associated proteins such as tropomyosin, a-actinin, filamin, etc.,’” and the microtubule-associated proteins (MAPS), both of which have been described extensively. Recently, IF-associated proteins (IFAPs) have also been described and activity in this area of study will undoubtedly increase in intensity in the near future.’.’ When considered together these three fiber systems and their associated proteins constitute a major proportion of total cell protein which collectively has become known as the cytoskeleton or the cytoskeletal system. Unfortunately, the term “cytoskeleton” when used in this fashion, is a misleading one, as it implies a lack of dynamic activity and further suggests that these three distinctive fibrous protein systems are similar with regard to their functions. This is certainly not the case and is contrary to well established facts that demonstrate that the three cytoplasmic fiber systems are distinctly different with regard to their subcellular organization, their relationship to different cell functions, their relative stabilities, and their biochemical and immunological properties.’-’ In spite of these considerations, numerous recent biochemical and molecular studies have emphasized associations of various cellular components (for example, nuclei, ribosomes, etc.) with nondescript “cytoskeletal elements” that are usually

Intermediate Filament Networks: Organization and Possible Functions of a Diverse Group of Cytoskeletal Elements

SUMMARY Immunofluorescence and electron microscopic observations demonstrate that intermediate filaments (IF) form cytoplasmic networks between the nucleus and cell surface in several types of cultured cells. Intermediate filaments interact with the nuclear surface, where they appear to terminate at the level of the nuclear envelope. From this region, they radiate towards the cell surface where they are closely associated with the plasma membrane. On the basis of these patterns of IF organization, we suggest that IF represent a cytoskeletal system interconnecting the cell surface with the nucleus. Furthermore, IF also appear to interact with other cytoskeletal components including microtubules and microfilaments. In the former case microtubule–IF interactions are seen in cytoplasmic regions between the nucleus and the cell membrane, whereas microfilament–IF interactions occur in the cortical cytoplasm. IF also appear to be cross-linked to each other; especially in the case of the IF bundles that occur in epithelial cells. In order to determine the molecular and biochemical bases of the organizational state of IF we have developed procedures for obtaining IF-enriched ‘cytoskeletons’ of cultured cells. In these preparations IF–nuclear and IF–cell surface associations are retained. Thus, these preparations have enabled us to begin to study various IF-associated structures (e.g. desmosomes) and associated proteins (IFAPs) using biochemical and immunological methodologies. To date, the results support the idea that IF and their associated proteins may comprise the cell type specific molecular infrastructure that is involved in transmitting and distributing information amongst the major cellular domains; the cell surface/extracellular matrix, the cytoplasm and the nuclear surface/nuclear matrix.

Immunotyping of radial glia and their glial derivatives during development of the rat spinal cord

SummaryThe differentiation of glia in the central nervous system is not well understood. A major problem is the absence of an objective identification system for involved cells, particularly the early-appearing radial glia. The intermediate filament structural proteins vimentin and glial fibrillary acidic protein have been used to define the early and late stages, respectively, of astrocyte development. However, because of the non-specificity of vimentin and the temporal overlap in expression patterns of both proteins, it is difficult to refine our view of the process. This is especially true of the early differentiation events involving radial glia. Using the developmentally-expressed intermediate filament-associated protein IFAP-70/280 kD in conjunction with vimentin and glial fibrillary acidic protein markers, a comprehensive investigation of this problem was undertaken using immunofluorescence microscopy of developing rat spinal cord (E13-P28 plus adult). The phenotypes of the cells were defined on the basis of their immunologic composition with respect to IFAP-70/280 kD (I), vimentin (V) and GFAP (G). A definitive immunotype for radial glia was established, viz, I+/V+/G−; thus reliance upon strictly morphological criteria for this early developmental cell was no longer necessary. Based upon the immunotypes of the cells involved, four major stages of macroglial development were delineated: (1) radial glia (I+/V+/G−); (2) macroglial progenitors (I+/V+/G+); (3) immature macroglia (I−/V+/G+); and (4) mature astrocytes (I−/V+/G+ primarily in white matter and I−/V−/G+, the predominant type in gray matter). It is of interest to note that the cells of the floor plate were distinguished from radial glia by their lack of IFAP-70/280 kD immunoreactivity. Introduction of the IFAP-70/280 kD marker has therefore provided a more refined interpretation of the various differentiation stages from radial glia to mature astrocytes.

A subpopulation of reactive astrocytes at the immediate site of cerebral cortical injury

We have identified an early-appearing intermediate filament-associated protein (IFAP-70/280 kDa) in radial glia and their immediate derivatives. This IFAP is absent in the adult CNS. In this study, we examined the reexpression of this early glial differentiation trait in rat reactive astrocytes induced by stab injury of the cerebrum. Double-label immunofluorescence microscopy demonstrated that by 36 h postlesion, IFAP-70/280 kDa was present in a few GFAP-positive astrocytes in the area adjacent to the wound. As the gliotic reaction progressed, the number of IFAP-positive reactive astrocytes increased and by 5-6 days postlesion, IFAP-70/280 kDa was present in most of the hypertrophied astrocytes in tissue immediately adjacent to the wound. By 8 days postlesion, while the number of IFAP-negative reactive astrocytes away from the wound diminished, the IFAP-containing reactive astrocytes close to the wound persisted. Concurrently, they began to change from a stellate form to an elongated shape, with their longitudinal axes radiating from the wound. The immunoreactivity of this IFAP started to diminish at 20 days postlesion, and by 30 days postlesion, it was not observed in the remaining gliotic cells. These results demonstrate that reactive astrocytes induced by stab-wound injury can be divided into two subtypes: persistent IFAP-70/280 kDa-containing cells which are close to the wound in the area of the glial scar and transient IFAP-70/280 kDa-negative cells which are farther from the wound. The reappearance of IFAP-70/280 kDa also suggests that some reactive astrocytes have the capacity to recapitulate early developmental stages.

Thrombin induces nestin expression via the transactivation of EGFR signalings in rat vascular smooth muscle cells

Regulation of nestin gene expression is largely unknown despite that it is widely used as a progenitor cell marker. In this study, we showed that nestin expression is regulated by the thrombin-mediated EGFR transactivation in serum-deprived primary cultures of rat vascular smooth muscle cells (VSMCs). This resulted from the direct binding of thrombin to PAR-1 rather than indirectly affecting through the binding to thrombomodulin, as demonstrated by thrombomodulin RNAi. In this process, the PAR-1-induced c-Src plays a critical role through two routes; one was the direct intracellular phosphorylation of EGFR and the other was the extracellular activation of the MMP-2-mediated shedding of HB-EGF. The transactivated EGFR then led to the downstream Ras-Raf-ERK signaling axis, but not the p38 or JNK pathways. In addition, the EMSA experiment showed that the transcriptional factor Sp1 is critical for the thrombin-induced nestin expression in rat VSMCs. Furthermore, RNAi of nestin attenuated the thrombin-induced cell proliferation, indicating that thrombin-induced nestin expression and cell proliferation share the same EGFR transactivation mechanism. This study also suggested that nestin may play an important role in cell proliferation induced by the thrombin-mediated EGFR transactivation.

Lysophosphatidic acid stimulates thrombomodulin lectin-like domain shedding in human endothelial cells.

Thrombomodulin (TM) is an anticoagulant glycoprotein highly expressed on endothelial cell surfaces. Increased levels of soluble TM in circulation have been widely accepted as an indicator of endothelial damage or dysfunction. Previous studies indicated that various proinflammatory factors stimulate TM shedding in various cell types such as smooth muscle cells and epithelial cells. Lysophosphatidic acid (LPA) is a bioactive lipid mediator present in biological fluids during endothelial damage or injury. In the present study, we first observed that LPA triggered TM shedding in human umbilical vein endothelial cells (HUVECs). By Cyflow analysis, we showed that the LPA-induced accessibility of antibodies to the endothelial growth factor (EGF)-like domain of TM is independent of matrix metalloproteinases (MMPs), while LPA-induced TM lectin-like domain shedding is MMP-dependent. Furthermore, a stable cell line expressing TM without its lectin-like domain exhibited a higher cell proliferation rate than a stable cell line expressing full-length TM. These results imply that LPA induces TM lectin-like domain shedding, which might contribute to the exposure of its EGF-like domain for EGF receptor (EGFR) binding, thereby stimulating subsequent cell proliferation. Based on our findings, we propose a novel mechanism for the exposure of TM EGF-like domain, which possibly mediates LPA-induced EGFR transactivation.

Keratin expression in astrocytomas: an immunofluorescent and biochemical reassessment

Abstract Several studies have shown that immunoenzymatic staining of formalin-fixed, paraffin-embedded astrocytomas with keratin antibodies frequently yields positive labelling, but no biochemical evidence of keratin expression in astrocytomas has been reported. We have investigated the presence of keratin in astrocytoma and normal brain tissues both by immunofluorescence on frozen sections and by 1D and 2D immunoblotting using seven monoclonal antibodies that, collectively, recognize most keratin polypeptides. Four of these antibodies did not stain neural tissues by immunofluorescence and were also negative by immunoblotting. The remaining three keratin antibodies stained normal brain and/or a high proportion of astrocytomas. Two of these three antibodies only stained glial fibrillary acidic protein (GFAP)-positive cells, while the third only stained GFAP-negative cells. 1D and 2D immunoblotting analysis showed that positive immunofluorescence staining of normal brain and/or astrocytomas seen with these three keratin antibodies was due to cross-reactivity with non-keratin proteins, such as GFAP. These results demonstrate that, contrary to earlier suggestions, keratin polypeptides are not frequently expressed in astrocytomas. Our studies also emphasize that keratin antibodies should be used cautiously for the differential diagnosis of undifferentiated gliomas from tumours of non-glial origin.

Thrombomodulin is an ezrin-interacting protein that controls epithelial morphology and promotes collective cell migration

Adhesive interactions between cells are needed to maintain tissue architecture during development, tissue renewal and wound healing. Thrombo‐modulin (TM) is an integral membrane protein that participates in cell–cell adhesion through its extracellular lectin‐like domain. However, the molecular basis of TM‐mediated cell–cell adhesion is poorly understood. Here, we demonstrate that TM is linked to the actin cytoskeleton via ezrin. In vitro binding assays showed that the TM cytoplasmic domain bound directly to the N‐terminal domain of ezrin. Mutational analysis of the TM cytoplasmic domain identified 522RKK524 as important ezrin‐binding residues. In epidermal epithelial A431 cells, TM colocalized with ezrin and actin filaments at cell–cell contacts. Knockdown of endogenous TM expression by RNA interference induced morphological changes and accelerated cell migration in A431 cells. Moreover, epidermal growth factor, upstream of ezrin activation, stimulated the interaction between ezrin and TM. In skin wound healing of mice, TM and ezrin were highly expressed in neoepidermis, implying that both proteins are key molecules in reepithelialization that requires collective cell migration of epithelial cells. Finally, exogenous expression of TM in TM‐deficient melanoma A2058 cells promoted collective cell migration. In summary, TM, which associates with ezrin and actin filaments, maintains epithelial morphology and promotes collective cell migration.—Hsu, Y.‐Y., Shi, G.‐Y., Kuo, C.‐H., Liu, S.‐L., Wu, C.‐M., Ma, C.‐Y., Lin, F.‐Y., Yang, H.‐Y., Wu, H.‐L. Thrombomodulin is an ezrin‐interacting protein that controls epithelial morphology and promotes collective cell migration. FASEB J. 26, 3440–3452 (2012). www.fasebj.org

Nestin Serves as a Prosurvival Determinant that is Linked to the Cytoprotective Effect of Epidermal Growth Factor in Rat Vascular Smooth Muscle Cells

Nestin is an intermediate filament protein mainly expressed in muscle and neural progenitors. Recently, we reported that nestin is expressed in rat vascular smooth muscle cells (VSMCs), disappears after serum-deprivation and then is re-expressed again following EGF stimulation. As the function of nestin in VSMCs remains unknown, its anti-apoptotic function was investigated in this study. We first showed that cell viability of nestin-depleted cells following H(2)O(2) treatments decreased by nestin RNAi. Further DNA laddering analysis and flow cytometry results demonstrated that this loss of cell viability was mediated through apoptosis. In addition, caspase-9, caspase-3 and PARP were activated in nestin-depleted VSMCs following H(2)O(2) treatments, indicating that nestin has an upstream inhibitory effect on caspase activation. It is well known that EGF serves as a survival factor in rat VSMCs. Here, we show that the cytoprotective effect of EGF was prevented by nestin RNAi. In addition, the inhibition of Cdk5 prevented Bcl-2 phosphorylation and enhanced H(2)O(2)-induced caspase-3 activation as well as subsequent DNA fragmentation. Taken together, these results provide evidence for another cytoprotective role of EGF in that it is mediated through its stimulation of nestin expression which leads to the prevention of caspase activation by Cdk-5-induced Bcl-2 phosphorylation in rat VSMCs.

Epidermal growth factor up-regulates the expression of nestin through the Ras-Raf-ERK signaling axis in rat vascular smooth muscle cells.

The contractile-synthetic phenotypic modulation of vascular smooth muscle cells (VSMCs) is a key event during atherosclerosis progression. Although many studies have reported possible cytokines and growth factors implicated to this process, the critical factors affecting the VSMC phenotype remain unclear due to the lack of early de-differentiation marker identifications. In this study, we showed that nestin, an intermediate filament protein, is expressed in primary cultures of rat VSMCs representing the synthetic phenotype and its expression is diminished as these cells re-differentiate after serum deprivation. However, the regulation of nestin expression was never reported despite its common usage as an early differentiation marker. Herein, we showed that nestin expression is regulated by epidermal growth factor (EGF) via de novo RNA and protein synthesis. Furthermore, signaling analyses revealed that the EGF-induced nestin re-expression is mediated through the activation of the Ras-Raf-ERK signaling axis. This is the first report to show that nestin expression is regulated by an extracellular signaling molecule.